metal-oxide- semiconductor (mos) · mos (metal-oxide-semiconductor) assume work function of metal...
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Metal-Oxide-Semiconductor (MOS)
EL-314N
Dr. M Jawaid Siddiqui
MOS (Metal-Oxide-Semiconductor)
Assume work function of metal and semiconductor are
same.
MOS materials
MOS structure
Shown is the semiconductor substrate with a thin oxide layer and a top metal contact, also referred to as the gate.
A second metal layer forms an Ohmic contact to the back of the semiconductor, also referred to as the bulk.
The structure shown has a p-type substrate.
We will refer to this as an n-type MOS capacitor since the inversion layer contains electrons.
Structure and principle of operation
To understand the different bias modes of an MOS we consider 3 different bias voltages.
(1) below the flatband voltage, VFB
(2) between the flatband voltage and the threshold voltage, VT, and
(3) larger than the threshold voltage.
These bias regimes are called the accumulation, depletion and inversion mode of operation.
Structure and principle of operation
Charges in a MOS structure under accumulation,
depletion and inversion conditions
Four modes of MOS operation
The four modes of operation of an MOS structure: Flatband,
Depletion,
Inversion and
Accumulation.
Flatband conditions exist when no charge is present in the semiconductor so that the Si energy band is flat.
Surface depletion occurs when the holes in the substrate are pushed away by a positive gate voltage.
A more positive voltage also attracts electrons (the minority carriers) to the surface, which form the so-called inversion layer.
Under negative gate bias, one attracts holes from the p-type substrate to the surface, yielding accumulation
MOS capacitor structure
MOS capacitor- accumulation
Accumulation occurs typically for -ve voltages where the
-ve charge on the gate attracts holes from the substrate
to the oxide-semiconductor interface.
Depletion occurs for positive voltages.
The +ve charge on the gate pushes the mobile holes into
the substrate.
Therefore, the semiconductor is depleted of mobile
carriers at the interface and a -ve charge, due to the
ionized acceptor ions, is left in the space charge region.
MOS capacitor- accumulation
MOS capacitor- flat band
The voltage separating the accumulation and depletion regime is referred to as the flatband voltage, VFB.
The flatband voltage is obtained when the applied gate voltage equals the workfunction difference between the gate metal and the semiconductor.
If there is a fixed charge in the oxide and/or at the oxide-silicon interface, the expression for the flatband voltage must be modified accordingly.
MOS capacitor- flat band
MOS capacitor- depletion
MOS capacitor- inversion
Inversion occurs at voltages beyond the
threshold voltage.
In inversion, there exists a negatively
charged inversion layer at the oxide-
semiconductor interface in addition to the
depletion-layer.
This inversion layer is due to minority
carriers, which are attracted to the interface
by the positive gate voltage.
MOS capacitor- inversion
MOS Capacitance
CV measurements of MOS capacitors provide a wealth of information about the structure, which is of direct interest when one evaluates an MOS process.
Since the MOS structure is simple to fabricate, the technique is widely used.
To understand CV measurements one must first be familiar with the frequency dependence of the measurement.
This frequency dependence occurs primarily in inversion since a certain time is needed to generate the minority carriers in the inversion layer.
Thermal equilibrium is therefore not immediately obtained.
Capacitance depends on frequency of applied signal.
If speed of variation is slow enough so that electrons can be generated by thermal generation fast enough to be created in phase with applied signal, then Cs is very large
If variation is too high a frequency, electron concentration remains fixed at the average value and capacitance depends on capacitance of depletion region
MOS Capacitance
Influence of gate on surface potential
Gate-depletion capacitive divider
Capacitance in series
CV Curve
CV Curve
CV Curve
C-V characteristic of p-type Semiconductor
nMOS
pMOS
C-V characteristic of n-type Semiconductor
Low frequency capacitance of an nMOS capacitor.
Shown are the exact solution for the low frequency capacitance (solid line) and the low and high frequency capacitance obtained with the simple model (dotted lines). Na= 1017 cm-3 and tox = 20 nm.
(a) The threshold
voltage and the
ideal MOS
structure
(b) In practice, there are several charges in the oxide and at the oxide-
semicond interface that effect the threshold voltage: Qmi = mobile ionic
charge, Qot = trapped oxide charge, Qf = fixed oxide charge, Qit =
charge trapped at the interface.
Effects of Real Surfaces
Charge Distribution
Key Definitions
Potential Definition
Depletion Width
Gate Voltage (depletion case)
δ-depletion capacitance
δ-depletion capacitance
n-Si
p-Si
Exact capacitance
C vs f
C vs f
C vs scan rate
Parallel plate capacitance
Parallel plate capacitance
An n-channel MOS transistor. The gate-oxide thickness, TOX, is approximately 100 angstroms (0.01 mm). A typical transistor length, L = 2 l. The bulk may be either the substrate or a well. The diodes represent pn-junctions that must be reverse-biased
Parallel plate capacitance
The channel and the gate form the plates
of a capacitor, separated by an insulator
- the gate oxide.
We know that the charge on a linear
capacitor, C, is
Q = C V
The channel charge, Q.
Parallel plate capacitance
At lower plate, the channel, is not a linear conductor.
Charge only appears on the lower plate when the voltage between the gate and the channel, VGC, exceeds the n-channel threshold voltage.
For nonlinear capacitor we need to modify the equation for a linear capacitor to the following:
Q = C(VGC – Vt)
Parallel plate capacitance
The lower plate capacitor is resistive and conducting current, so that the VGC varies.
In fact, VGC = VGS at the source and VGC = VGS – VDS at the drain.
What we really should do is find an expression for the channel charge as a function of channel voltage and sum (integrate) the charge all the way across the channel, from x = 0 (at the source) to x = L (at the drain).
Instead we shall assume that the channel voltage, VGC(x), is a linear function of distance from the source and take the average value of the charge, which is
Q = C [(VGS – Vt) – 0.5 VDS]
Parallel plate capacitance
The gate capacitance, C, is given by the formula for a
parallel-plate capacitor with length L , width W , and
plate separation equal to the gate-oxide thickness, Tox.
Thus the gate capacitance is
C = (W L eox)/Tox = W L Cox
where eox is the gate-oxide dielectric permittivity
For SiO2 , eox ~ 3.45 x 10–11 Fm–1, so that, for a typical
gate-oxide thickness of 100 Å (= 10 nm), the gate
capacitance per unit area, Cox ~ 3 fFmm–2.
The channel charge of transistor
The channel charge in terms of the transistor parameters
Q = WL Cox [(VGS – Vt) – 0.5 VDS]
The drain–source current is
IDS = Q/tf= (W/L) mn Cox [(VGS – Vt) – 0.5 VDS] VDS
= (W/L)k'n [(VGS – Vt) – 0.5 VDS] VDS ......(*)
The tf is time of flight - sometimes called the transit time is the time that it takes an electron to cross between source and drain.
mn is the electron mobility (mp is the hole mobility)
The channel charge of transistor
The constant k'n is the process
transconductance parameter (or intrinsic
transconductance ):
k'n = mn Cox
We also define bn , the transistor gain factor
(or just gain factor ) as
bn = k'n (W/L)
The factor W/L is the transistor shape factor.
The channel charge of transistor
Equation (*) describes the linear region (or triode region) of operation.
This equation is valid until VDS = VGS – Vt and then predicts that IDS decreases with increasing VDS.
At VDS = VGS – Vt = VDS(sat) (the saturation voltage ) there is no longer enough voltage between the gate and the drain end of the channel to support any channel charge.
Clearly a small amount of charge remains or the current would go to zero, but with very little free charge the channel resistance in a small region close to the drain increases rapidly and any further increase in VDS is dropped over this region.
Thus for VDS > VGS – Vt (the saturation region, or pentode region, of operation) the drain current IDS remains approximately constant at the saturation current, IDS(sat) , where
IDS(sat) = (bn/2)(VGS – Vt)2; VGS > Vt ..... (**)
The channel charge of transistor
Figure below shows the n-channel transistor I-
V characteristics for a generic 0.5 mm CMOS
process that we shall call G5 .
We can fit Eq.(**) to the long-channel
transistor characteristics (W = 60 mm, L = 6
mm).
If IDS(sat) = 2.5 mA (with VDS = 3.0 V, VGS = 3.0
V, Vt = 0.65 V, Tox =100 Å), the intrinsic
transconductance is
The channel charge of transistor
MOS n-channel transistor
characteristics for a generic 0.5 mm
process (G5). (a) A short-channel
transistor, with W=6 mm and L=0.6
mm (drawn) and a long-channel
transistor (W=60 mm, L=6 mm)
(b) The 6/0.6 characteristics
represented as a surface. (c) A
long-channel transistor obeys a
square-law characteristic between
IDS and VGS in the saturation region
(VDS = 3 V). A short-channel
transistor shows a more linear
characteristic due to velocity
saturation. Normally, all of the
transistors used on an ASIC have
short channels.
(a)
The channel charge of transistor
MOS n-channel transistor
characteristics for a generic 0.5 mm
process (G5). (a) A short-channel
transistor, with W=6 mm and L=0.6
mm (drawn) and a long-channel
transistor (W=60 mm, L=6 mm)
(b) The 6/0.6 characteristics
represented as a surface. (c) A
long-channel transistor obeys a
square-law characteristic between
IDS and VGS in the saturation region
(VDS = 3 V). A short-channel
transistor shows a more linear
characteristic due to velocity
saturation. Normally, all of the
transistors used on an ASIC have
short channels.
(b)
The channel charge of transistor
MOS n-channel transistor
characteristics for a generic 0.5 mm
process (G5). (a) A short-channel
transistor, with W=6 mm and L=0.6
mm (drawn) and a long-channel
transistor (W=60 mm, L=6 mm)
(b) The 6/0.6 characteristics
represented as a surface. (c) A
long-channel transistor obeys a
square-law characteristic between
IDS and VGS in the saturation region
(VDS = 3 V). A short-channel
transistor shows a more linear
characteristic due to velocity
saturation. Normally, all of the
transistors used on an ASIC have
short channels.
(c)
The channel charge of transistor
k'n = [2(L/W) IDS(sat)] /(VGS – Vt)2
= [2(6/60) (2.5x10–3 )]/[(3.0 – 0.65)2]
= 9.05 x 10–5 AV–2 ~ 90 mAV–2
This value of k'n, calculated in the saturation region, will be different (typically lower by a factor of 2 or more) from the value of k'nmeasured in the linear region.
We assumed the mobility, mn, and the threshold voltage, Vt, are constants.
The channel charge of transistor
For the p-channel transistor in the G5
process, IDS(sat) = –850 mA (VDS = –3.0 V,
VGS = –3.0 V, Vt = –0.85 V, W = 60 mm, L
= 6 mm). Then
k'p = [2(L/W) IDS(sat)] /(VGS – Vt)2
= [2(6/60) (850x10–6)]/[(–3.0 – (–0.85))2]
= 3.68 x 10–5 AV–2
P-channel MOS transistor
The source and drain of CMOS transistors look identical.
The source of an n-channel transistor is lower in potential than the drain and vice versa for a p-channel transistor.
In an n-channel transistor the threshold voltage, Vt, is normally positive, and the terminal voltages VDS and VGS are also usually positive.
In a p-channel transistor Vt is normally negative and we have a choice: We can write everything in terms of the magnitudes of the voltages and currents or we can use negative signs in a consistent fashion.
P-channel MOS transistor
P-channel MOS transistor
Here are the equations for a p -channel transistor using negative signs:
IDS = –k'p (W/L)[(VGS–Vt) – 0.5 VDS] VDS ; VDS > VGS –Vt
IDS(sat) = – bp/2 (VGS – Vt)2; VDS < VGS – Vt
In these two equations Vt is negative, and VDS & VGS
are also normally negative (–3 V < –2 V, for example). The IDS is then negative, corresponding to conventional current flowing from source to drain of a p-channel transistor (and hence the negative sign for IDS(sat)).
MOSFET Capacitances
Overlap Capacitance